ES2651342T3 - Device and method of administration of a therapeutic agent - Google Patents

Abstract

A particle therapeutic agent delivery device comprising: a respiratory gas channel (13) having an end for the patient (16) in which a patient may be pneumatically connected; a particle therapeutic agent channel (19) having a solid particle therapeutic agent therein in pneumatic communication with the respiratory gas channel; a gas scrubber housing (22) in pneumatic communication with the respiratory gas channel, the gas scrubber housing has an exhaled gas orifice (25) to receive the exhaled gas from the respiratory gas channel; and a gas scrubber material (26) located inside the housing such that it receives the exhaled gas comprising the particulate therapeutic agent through the exhaled gas orifice and remove carbon dioxide from the exhaled gas to provide a gas treated comprising the particulate therapeutic agent, and located so that the treated gas is provided to the respiratory gas channel, and in which the gas scrubber housing includes an electrically conductive material.

Description

DESCRIPTION

Device and method of administration of a therapeutic agent Field of the invention

[0001] The present invention relates to methods and devices for administering therapeutic agents to the lungs of a patient.

10 Background of the invention

[0002] A particulate therapeutic agent may be transported by a carrier gas to a patient's lungs to treat the patient. For example, the carrier gas may be oxygen and the therapeutic agent may be liquid particles or solid particles. Such a mixture can be an aerosol. Such a mixture can be formed by the

15 nebulization of a liquid in the carrier gas. This method of administration can be advantageous when the therapeutic agent is directed to a specific site of action that is easily accessed by inspiration, or when the pulmonary absorption of a therapeutic agent in the systemic circulation is suboptimal or when the systemic blood levels of A therapeutic agent will be minimized. Examples of therapeutic agents that can be administered in this manner include bronchodilators, steroids, antibiotics, mucolytics, lytic enzymes of DNA and genetic vectors for the treatment of a lung disease. For example, antifungal and antiviral agents have been administered in the form of aerosols. In addition, chemotherapeutic agents for pulmonary neoplasia and a series of pulmonary therapies that have potential systemic toxicity or undesirable systemic side effects have been nebulized. Additional therapies may include the administration of surfactants, the administration of perfluorocarbon and the administration of liposomal drugs.

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[0003] The respiratory cycle of a human being consists of inspiration and expiration. Inspiration represents approximately% of the respiratory cycle and expiration represents approximately% of the respiratory cycle. If a therapeutic agent continually exceeds a patient's mouth, approximately one% of the therapeutic agent may not be inspired, and therefore may be wasted. In addition, the therapeutic agent that

30 is inspired can only be partially captured by the lung. For certain therapeutic agents, such as surfactants, more than 90% of the inspired therapeutic agent can be subsequently exhaled (instead of being retained in the lung) and thus exhaled air is lost. This effect may be greater when the therapeutic mixture has particles that are especially small, as may be the case when the therapeutic agent has a low surface tension (similar to surfactant and perfluorocarbon) or is a liquid with a high density ( similar to perfluorocarbons).

[0004] A solution to these dosing inefficiencies is to breathe again the exhaled gas, thus renewing the opportunity to retake the therapeutic agent instead of losing it in the environment after expiration. If a "single pulse" of the therapeutic agent could be breathed again and again, the final absorption could approximate

40 to 100%. The same can be said of a "pulsation" followed by prolonged breath containment. Repeated reinspiration of the same "pulsation, or prolonged containment of respiration may result in hypoxia, hypercapnia, discomfort, or may prolong the time necessary to administer a required dose of the therapeutic agent. In addition, a high level of cooperation by the patient These problems complicate, if not avoided, the use of these strategies to administer a therapeutic agent.

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[0005] A solution to these problems consists in intermittent administration, in which only the therapeutic agent is provided during inspiration. This solution offers a significant gain in efficiency over continuous dosing, but is still limited in its usefulness due to the loss of therapeutic agent not absorbed in the environment during expiration. This solution can be combined with breath containment.

50 to further reduce expiration losses, but the breath containment strategy may limit the rate of administration of the therapeutic agent and may require a high level of cooperation from the patient.

[0006] Document DE 3742880 describes an xenon inhalation apparatus that uses bellows capable of varying its volume for the gas stored therein to thereby manage the gas on the basis both

55 of the gas volume as a gas concentration, avoid excessive consumption of xenon that is expensive in the preparation of a mixed gas of an addition xenon and recover the xenon and also using a blower to thereby administer a mixed gas High precision to a patient without using one-way valves in the same circumstances as that obtained by the use of one-way valves.

[0007] US 4,127,121 describes an oxygen monitoring device with a system

closed for the simultaneous introduction, monitoring and control of the concentration level of anesthetic gas. The device comprises a closed recirculation administration circuit for the administration of a present volume of oxygen and gas anesthesia to a surgical patient. An oxygen sensor contained in the closed circuit monitors 5 decreases the concentration of oxygen in the recirculation system and triggers the restoration to the current value by means of sets of feedback comparator circuits. The desired amount of anesthetic gas is present and is maintained by a potentiometric monitoring device operative in response to the peak expansion of respirator bellows contained in the circuit.

[0008] EP 0861672 describes a method of forming a gas mixture of

breathing.

[0009] EP 0761249 describes an anesthesia apparatus with a dosage unit (16) for an anesthetic agent. The dosage unit (16) comprises a plurality of containers, each of the

15 which houses a liquid anesthetic agent.

[0010] US 6,041,777 describes procedures and apparatus that allow closed circuit ventilation for the treatment or diagnosis of disorders.

20 Summary of the invention

[0011] According to one aspect of the invention, a device for administering the therapeutic agent in particles according to claim 1 is provided.

[0012] In a process according to the description, a particulate therapeutic agent is provided to the

a patient's respiratory system A carbon dioxide gas scrubber can be provided in pneumatic communication with the respiratory system, and exhaled gas from the respiratory system can be provided to the gas scrubber. The exhaled gas can be passed through the gas scrubber to provide a treated gas, which can be provided to the respiratory system. By such a procedure, a particulate therapeutic agent that was present in the exhaled gas can be breathed again by the patient.

Brief description of the drawings

[0013] For a more complete understanding of the nature and objects of the invention, it should be made

35 reference to the following detailed description taken in conjunction with the accompanying drawings, in which:

Fig. 1 is a schematic diagram of a therapeutic agent delivery device according to an embodiment of the invention;

Fig. 2 is a schematic diagram of a therapeutic agent delivery device according to an embodiment 40 of the invention;

Fig. 3 is a schematic diagram of a therapeutic agent delivery device according to an embodiment of the invention;

Fig. 4 is a schematic diagram of a therapeutic agent delivery device according to an embodiment of the invention;

Fig. 5 is a schematic diagram of a therapeutic agent delivery device according to an embodiment of the invention;

Fig. 6 is a schematic diagram of a therapeutic agent delivery device according to an embodiment of the invention;

Fig. 7 is a schematic diagram of a therapeutic agent delivery device according to an embodiment 50 of the invention; Y

Fig. 8 is a block diagram of a process according to the invention.

Detailed description of the invention

[0014] Figure 1 is a schematic representation of an embodiment of an administration device

of therapeutic agent in particles 10 according to the invention. The delivery device 10 has a respiratory gas channel 13 that has an end for the patient 16 in which a patient can be pneumatically connected. The respiratory gas channel 13 may include an endotracheal tube that can be inserted into a patient's trachea.

[0015] The delivery device 10 has a particulate therapeutic agent channel 19 in pneumatic communication with the respiratory gas channel 13. An aerosol generator 28 can be provided in pneumatic communication with the particulate therapeutic agent channel 19. The generator Aerosol 28 may be a nebulizer, for example, a jet nebulizer or an ultrasonic nebulizer. The respiratory gas channel 13

5 may include a mixing chamber 29, which can provide a location for the therapeutic agent to disperse and mix with respiratory gas.

[0016] A gas scrubber housing 22 is in pneumatic communication with the respiratory gas channel 13. The gas scrubber housing 22 includes an electrically conductive material such that a charge

10 does not develop, and thereby causes the therapeutic agent to be collected in the gas scrubber housing 22. The gas scrubber housing 22 may have an exhaled gas orifice 25, which can be used to receive the gas exhaled from the respiratory gas channel 13. A gas scrubber material 26 is disposed inside the gas scrubber housing 22. A portion of the gas scrubber material 26 is illustrated in Figure 1. The gas scrubber material 26 it can be located inside the casing of the 15 gas scrubber so that it receives exhaled gas through the exhaled gas orifice 25. The gas scrubbing material 26 can be soda lime. The gas washing material 26 is positioned in order to remove carbon dioxide from the exhaled gas to provide a treated gas, and in order to provide the treated gas to the respiratory gas channel 13.

[0017] Figure 1 shows that the particulate therapeutic agent channel 19 may be in pneumatic communication 20 with an agent delivery location 31 in the respiratory gas channel 13. The location of the

agent administration 31 may be located such that the general gas flow from the exhaled gas orifice 25 to the end patient 16 passes through the agent administration location 31.

[0018] A fan 85 may be provided in pneumatic communication with the respiratory gas channel 25 13. In this invention, references to "fan" are intended to include devices that provide a force

which aims to move the respiratory gas to a patient through the respiratory gas channel 13. This definition is intended to include devices usually called "respirators", as well as devices usually called "fans." A portion of the fan 85, such as a flexible diaphragm or accordion sleeve, can be moved to force the therapeutic agent into the respiratory gas channel 13 into the respiratory system.

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[0019] The ventilator 85 may be in pneumatic communication with an expiration tank 52. The expiration tank 52 may serve to provide an area in which the gas having therapeutic agent can be stored for future inspiration by the patient.

[0020] Figure 2 is a schematic of an embodiment of the administration device 10 having a first

channel 37 that goes from the respiratory gas channel 13 to the aerosol generator 28, and a second channel 40 that goes from the aerosol generator 28 to the respiratory gas channel 13. A pump 43 can be provided inside this circuit in order to move the gas from the respiratory gas channel 13 through the aerosol generator 28 and return to the respiratory gas channel 13.

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[0021] The embodiment of Figure 2 shows an exhaust valve 55 at one end of the exhalation tank 52. The exhaust valve 55 can serve to reduce the loss of therapeutic agents from the delivery device 10. The exhaust valve 55 is Can set to release gas during exhalation. The exhaust valve 55 can be adjusted in order to maintain a pressure inside the delivery device 10 in a

45 acceptable range.

[0022] Figure 3 is a diagram of another embodiment of an administration device 10 according to the invention. In this delivery device 10, a polarization gas channel 46 is provided in pneumatic communication with the respiratory gas channel 13. A polarization gas source 49 can supply

50 a polarization gas through the polarization gas channel 46 to the respiratory gas channel 13. The polarization gas may be intended to maintain the desired partial oxygen pressure for the patient.

[0023] Figure 4 shows the polarization gas source 49 and the polarization gas channel 46 located in a different location from that shown in Figure 3. The polarization gas channel 46 is shown in

Pneumatic communication with an exhalation tank 52, which may be similar to that described above.

[0024] Figure 5 is a diagram of an administration device 10 in which the gas scrubber housing 22 has a treated gas orifice 73 and the administration device 10 includes a treated gas channel 76 located so as to provide pneumatic communication between the treated gas orifice 73 and the gas channel

Respiratory 13. Area 88 identifies a portion of the device 10 which is known as a "circular circuit", so named because there is a path along which the gas can flow in a circular manner. An inspiration check valve 79 may be provided in the circular circuit 88, for example, near one end of the treated gas channel 76. The inspiration check valve 79 may be oriented to open during inspiration and close during expiration . The inspiration check valve 79 may be positioned and oriented so as to partially prevent the gas washing gas from re-entering the respiratory gas channel, which could occur during inspiration, to stimulate a particulate therapeutic agent. in the respiratory gas channel 13 to flow generally towards the end for the patient 16 during inspiration, stimulate a treated gas to flow generally away from the exhaled gas orifice 25, prevent the gas from being diverted through the housing of the gas scrubber 10 22 during expiration, or any combination of these.

[0025] An exhalation check valve 82 can be provided in the circular circuit 88. The exhalation check valve 82 may be oriented to open during expiration and close during inspiration. Expiration check valve 82 may be positioned and oriented in order to partially avoid

15 that the gas washing gas re-enters the respiratory gas channel, which could otherwise occur during inspiration, to stimulate a particulate therapeutic agent in the respiratory gas channel 13 to generally flow towards the end to the patient 16 during inspiration, stimulate a treated gas to flow generally away from the exhaled gas orifice 25, prevent the expired gas from being diverted by the gas scrubber housing 22 during expiration or any combination thereof.

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[0026] Figures 6 and 7 are schematics of other embodiments of an administration device 10 according to the invention, which include features previously described in this invention. In Figures 6 and 7, the gas scrubber housing 22 is not inside the circular circuit 88. In these embodiments, the exhaled gas can enter the gas scrubber housing 22 through the exhaled gas orifice 25 during exhalation, and gas

25 treated leaves the gas scrubber housing 22 through the exhaled gas orifice 25 during inspiration. Like the administration device 10 shown in Figure 5, the administration devices 10 in Figures 6 and 7 may have the inspiration check valve 79 and the exhalation check valve 82 positioned and oriented in order to avoid partially that the gas washing gas re-enters the respiratory gas channel, which could otherwise occur during inspiration, to stimulate a particulate therapeutic agent 30 in the respiratory gas channel 13 to generally flow towards the end for patient 16 during inspiration, stimulate a treated gas to flow generally away from the exhaled gas orifice 25, or any combination thereof.

[0027] In a process according to the description, a particulate therapeutic agent can be administered. Figure 8 is a block diagram of one such procedure. In that procedure, you can

a patient having a respiratory system 100 is provided. A particulate therapeutic agent can be provided to the respiratory system 103. The therapeutic agent 103 can be provided by nebulization of the therapeutic agent in a gas that is then provided 103 to the respiratory system. A carbon dioxide gas scrubber can be provided 106 in pneumatic communication with the respiratory system. The exhaled gas from the respiratory system can be provided 109 to the gas scrubber, and 112 can be passed through the gas scrubber to provide a treated gas. The treated gas can be described as having a lower partial pressure of CO2 than the exhaled gas. The treated gas can then be provided 115 to the respiratory system. A fan can be provided, and portions of the fan can be moved in order to force the therapeutic agent into the respiratory system. The ventilator may or may not be in pneumatic communication with the patient.

[0028] The process can provide a high polarization flow of the oxygen fraction to prevent hypoxia, while maintaining a low polarization flow rate in order to minimize expiratory debris. At a polarization flow (recent gas) of 10% of normal ventilation per minute, it is believed that only

About 6% of the expiratory flow escapes into a circular circuit according to the invention; The rest will be inspired again. If the particulate therapeutic agent is added during expiration, it is believed that most of the therapeutic agent administered during expiration is inspired during subsequent breathing, thus eliminating residues of therapeutic agent during the expiration phase. Hypoxia and hypercapnia are avoided. No special breathing maneuvers are required, and the patient is still comfortable.

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[0029] In a method according to the description, the therapeutic agent re-inhalation therapeutic agent is used to increase the concentration of the therapeutic agent that is administered to a patient during inspiration, thereby increasing both the administration and absorption of the therapeutic agent. . This should be contrasted with the prior art procedures in which reinspiration is merely used for

conserve volatile agents and gases during anesthesia. In anesthetic applications of the prior art, the anesthetic concentration of the circular circuit is regulated to achieve a desired alveolar gas concentration for anesthesia. In such an anesthetic application, reducing the flow of polarization reduces the amount of anesthetic agent required for anesthesia, and is not used to increase the concentration of therapeutic agent in order to enhance absorption by the lungs.

[0030] The invention should essentially increase the opportunity for pulmonary absorption of a given amount of therapeutic agent, unless the gas scrubber or the reinspiration circuit eliminates a large amount of therapeutic agent. To assess the extent to which a reinspiration circuit could eliminate an agent

Therapeutic administered as a fine particle aerosol, the rate of cigarette smoke loss, which is a fine particle aerosol, was measured from a circular circuit of soda lime. It was discovered that only 11% to 13% of smoke particles were consumed by the circuit in 3 seconds, the approximate duration of a respiratory cycle. Since the removal rate of a fine particle aerosol through the circuit of the recycled breathing system appears to be low, substantial efficiency must be acquired by the re-inhalation of particulate therapeutic agents through a gas scrubber of carbon. In addition, it was found that by the administration of smoke in a reinspiration circuit, the concentration of smoke in the air administered to a model lung increased sevenfold.

[0031] A procedure according to the description may require little or no cooperation on the part of the patient. In theory, a procedure according to the description may be more efficient than the procedures of the

prior technique of administration of therapeutic agents, and therefore perhaps more cost effective. In addition, a procedure according to the description can be used during prolonged dosing of both spontaneously breathing patients and mechanically ventilated patients.

[0032] Aerosol administration for non-reinspiration is safe for the patient who breathes air

ambient. However, the reinspiration procedure described in this application cannot be used safely without a high fraction of inspired oxygen. Therefore, the procedure may be limited to patients who have access to oxygen or gas mixtures enriched with oxygen.

Claims (10)

1. A particle therapeutic agent delivery device comprising: 5 a respiratory gas channel (13) having an end for the patient (16) in which a patient may be pneumatically connected; a particle therapeutic agent channel (19) having a solid particle therapeutic agent therein in pneumatic communication with the respiratory gas channel; a gas scrubber housing (22) in pneumatic communication with the respiratory gas channel, the gas scrubber housing has an exhaled gas orifice (25) to receive the exhaled gas from the respiratory gas channel; Y a gas washing material (26) located inside the housing such that it receives the exhaled gas comprising the particulate therapeutic agent through the exhaled gas orifice and remove carbon dioxide from the exhaled gas to provide a treated gas comprising the particulate therapeutic agent, and positioned so that the treated gas is provided to the respiratory gas channel, and wherein the gas scrubber housing includes an electrically conductive material. 2. The delivery device of claim 1, wherein the particulate therapeutic agent channel is in pneumatic communication with an agent delivery location (31) in the gas channel 20, the agent administration location is located so that a general gas flow from the exhaled gas orifice to the end for the patient passes through the agent administration location. 3. The delivery device of claim 1, further comprising an aerosol generator (28) in pneumatic communication with the particulate therapeutic agent channel. 25 4. The delivery device of claim 1, wherein the aerosol generator is a nebulizer. 5. The administration device of claim 1, further comprising a first channel (37) 30 that goes from the respiratory gas channel to the aerosol generator, and a second channel (40) that goes from the generator aerosol to the respiratory gas channel. 6. The administration device of claim 1, wherein the gas washing material is soda lime. 35 7. The administration device of claim 1, wherein the gas scrubber housing has a treated gas orifice (73), and the administration device further comprises a treated gas channel (76) located so as to provide pneumatic communication between the treated gas orifice and the respiratory gas channel, so that the gas passing through the gas scrubber housing is supplied to the respiratory gas channel. 40 8. The delivery device of claim 1, further comprising a check valve (79,82) positioned and oriented in the delivery device for stimulating a particulate therapeutic agent in the respiratory gas channel to generally flow towards the end for the patient during inspiration. Four. Five The administration device of claim 1, further comprising a check valve (79.82) positioned and oriented in the administration device to prevent exhaled gas from being diverted by the gas scrubber housing during expiration. The administration device of claim 1, further comprising a fan (85) in pneumatic communication with the respiratory gas channel. 11. The administration device of claim 1, further comprising a reservoir of exhalation (52) in pneumatic communication with the gas scrubber housing (22) and an exhaust valve (55) 55 at one end of the exhalation tank.